KR20160103960A - Device for neutron capture therapy and method for neutron ray measuring - Google Patents

Abstract

Provided is a device for neutron capture therapy, capable of measuring a neutron dose in real time while suppressing reduction in measurement accuracy of a neutron beam. The device for the neutron capture therapy includes: a real-time dose output unit (40) including a scintillation detector (41) for detecting a neutron beam (N) and outputting a signal in real time, and a neutron dose output unit (44) for converting the signal, outputted from the scintillation detector (41), into a neutron dose using a correction coefficient (45) and outputting the neutron dose in real time; and a correction coefficient setting unit for setting the correction coefficient (45). The correction coefficient setting unit includes a gamma ray detection section for detecting a gamma ray generated from a gold wire activated by irradiation of the neutron beam, and modifies the correction coefficient (45) based on a signal outputted from the scintillation detector (41) by irradiation of the neutron beam, and a dose of the neutron beam obtained based on the gamma ray detected by the gamma ray detection section.

Description

[0001] The present invention relates to a neutron capture device and a neutron capture device,

The present application claims priority based on Japanese Patent Application No. 2013-108339 filed on May 22, 2013. The entire contents of which are incorporated herein by reference.

TECHNICAL FIELD [0001] The present invention relates to a neutron capture therapy apparatus for irradiating a neutron beam to an object to be irradiated, and a neutron beam measurement method.

Boron neutron capture therapy (BNCT) using a boron compound is known as a neutron capture therapy for killing cancer cells by irradiation of a neutron beam. In the case of boron neutron capture therapy, a drug containing boron is administered to a patient to accumulate boron at a site where cancer cells are present, and the cancer cells are killed by irradiating neutrons to the site where the boron is accumulated.

Patent Document 1 discloses an apparatus for neutron capture therapy used in such neutron capture therapy. The apparatus includes a neutron emitting device for emitting a neutron beam toward an object to be irradiated, a vacuum conduit for guiding a neutron beam emitted from the neutron emitting device to an object to be irradiated, And a collimator for focusing the neutron beam to enhance the directivity of the neutron beam. In the therapeutic neutron irradiation apparatus of Patent Document 1, a test irradiation process for conducting a test irradiation of a neutron beam to an object to be irradiated is carried out. In this test irradiation process, the object to be irradiated is irradiated with a neutron beam, The actual amount of radioactivity at the time when the radioactivity is measured is measured. Specifically, a gold wire for neutron measurement is attached to the surface and the deep part of the target site in the object to be irradiated, the neutron beam is irradiated for a predetermined time and then the gold wire is taken out and the radiation amount of the gold wire is measured, .

Prior art literature

(Patent Literature)

Patent Document 1: JP-A-2004-233168

As described above, in the case where the neutron beam irradiated by measurement of the amount of radiation of the gold wire is mounted by placing the gold wire on the target site to be irradiated, the neutron beam is irradiated to the gold wire for a predetermined time, The dose of the line should be measured. Thus, since the dose of the neutron beam must be measured after the irradiation, there is a problem that the dose of the neutron beam can not be measured during the irradiation of the neutron beam, and real-time measurement of the neutron dose is impossible.

In addition, when a scintillation detector that emits radiation by receiving radiation or an ionization box that generates current by ionizing gas between electrodes by receiving radiation is used, real-time measurement of the neutron beam is possible because the signal is output by receiving the neutron beam. Do. However, in the scintillation detector, there is a problem that the scintillator, the optical fiber, and the like are deteriorated by the irradiation of the neutron beam, and the detection efficiency of the neutron beam is gradually lowered. Further, in the ionization box, there is a problem that the detection efficiency of the neutron beam changes when the deterioration of the gas between the electrodes due to the irradiation of the neutron beam or the change of the gas pressure occurs. If the detection efficiency of the neutron beam changes in this way, the signal state with respect to the amount of actually irradiated neutron beam is gradually changed, which causes a problem that the measurement accuracy of the neutron beam is lowered.

In view of the above problems, it is an object of the present invention to provide a neutron capture therapy apparatus and a neutron beam measurement method capable of real-time measurement of a neutron dose and suppressing a decrease in measurement accuracy of a neutron beam.

The neutron capture therapy apparatus of the present invention is a neutron capture therapy apparatus for irradiating a neutron beam to a specimen. The neutron capture apparatus includes a neutron beam generating unit for generating a neutron beam, a neutron beam generating unit for generating a neutron beam, A neutron beam detector for detecting a neutron beam irradiated from the neutron beam irradiator and outputting a signal in real time, and a neutron beam detector for converting the signal output from the neutron beam detector into a neutron beam dose using a preset conversion condition, And a conversion condition setting unit for setting a conversion condition, wherein the conversion condition setting unit is configured to detect a gamma ray generated from the metal member that has been spontaneously irradiated with the neutron beam when the neutron beam irradiation unit is irradiated with the neutron beam, And a gamma ray detection unit for detecting a neutron beam, Based on the neutron dose neutron line obtained on the basis of the signal, and a gamma ray detected by the gamma ray detector output from chulbu and characterized by modifying the conversion conditions.

According to the neutron capture therapy apparatus of the present invention, the neutron beam detection unit detects the neutron beam irradiated by the neutron beam irradiation unit, outputs a signal in real time, and converts the signal into a neutron beam dose using a predetermined conversion condition And outputs the neutron dose in real time. By providing the real-time dose output unit having the neutron beam detection unit and the neutron dose output unit as described above, it is possible to output the neutron dose in real time when the treatment is performed by irradiating the neutron beam. The conversion condition setting section includes a gamma ray detecting section for detecting a gamma ray generated from the metal member that has been emitted by irradiation with the neutron beam and detects a signal output from the neutron beam detecting section by detecting the neutron beam and a signal detected by the gamma ray detecting section And corrects (updates) the above conversion conditions based on the neutron dose acquired based on the gamma ray. Therefore, even if the detection efficiency of the neutron beam detecting unit for outputting the signal is reduced by modifying the conversion conditions by using the signal from the neutron beam detecting unit and the neutron beam dose obtained from the metal member, the signal is corrected to the neutron dose with the corrected conversion condition , It is possible to eliminate the deviation of the measured neutron dose with respect to the actually irradiated neutron dose. Therefore, it is possible to avoid the situation that the measurement accuracy of the neutron beam is lowered by converting the signal into the neutron dose with the modified conversion condition and outputting it.

The neutron beam detection unit may be a scintillator that generates an optical signal as a signal by being irradiated with a neutron beam. By using the scintillator as the neutron beam detecting unit, the neutron beam detecting unit can be downsized.

A neutron beam measurement method according to the present invention is a neutron beam measurement method in a neutron capture therapy apparatus for irradiating a neutron beam to a specimen. The neutron beam generation step for generating a neutron beam, the neutron beam generation step for generating a neutron beam, A neutron beam irradiation step of irradiating the neutron beam to the object to be irradiated; and a neutron beam detection unit that outputs a signal in real time by detecting the neutron beam irradiated in the first neutron beam irradiation step, And a conversion condition setting step of setting a conversion condition, wherein the conversion condition setting step is a step of setting a conversion condition setting step of setting a conversion condition setting step of setting a conversion condition setting step of setting a conversion condition setting step of setting a conversion condition setting step A second neutron beam irradiating step of irradiating a neutron beam at a second neutron beam irradiating step, A gamma ray detection step of detecting a gamma ray generated from the radioactive metal member; and a gamma ray detection step of detecting, based on the signal outputted from the neutron beam detection part by irradiation of the neutron beam and the neutron beam amount of the neutron beam acquired based on the gamma ray detected in the gamma ray detection step And a conversion condition calculating step of correcting the conversion condition.

According to the neutron beam measuring method of the present invention, the neutron beam detecting section detects the neutron beam, outputs a signal in real time, converts the signal into the neutron beam dose in the real time dose outputting step, The dose is output in real time. Since the signal is outputted in real time and the signal is converted into the neutron dose in real time in this way, the neutron dose can be output in real time when the neutron beam is irradiated and treated. In the conversion condition calculating step, the conversion condition is corrected (updated) based on the neutron beam detected based on the signal outputted from the neutron beam detecting unit and the gamma ray detected from the metal member in the gamma ray detecting step . Thus, even if the detection efficiency of the neutron beam detecting unit for outputting the signal is reduced by modifying the conversion condition using the signal outputted by the neutron beam detecting unit and the neutron beam amount obtained from the metal member, the signal is converted into the neutron beam dose , It is possible to eliminate the deviation of the measured neutron dose with respect to the actually irradiated neutron dose. Therefore, it is possible to avoid the situation that the measurement accuracy of the neutron beam is lowered by converting the signal into the neutron dose with the modified conversion condition and outputting it.

According to the present invention, real time measurement of the neutron dose can be performed, and deterioration of the measurement accuracy of the neutron beam can be suppressed.

BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a diagram showing the arrangement of a neutron capture therapy apparatus according to the present embodiment. FIG.
Fig. 2 is a diagram showing the neighborhood of the neutron beam irradiation part in the neutron capture therapy apparatus of Fig. 1; Fig.
Fig. 3 is a view for explaining measurement of neutron beams in the neutron capture therapy apparatus of Fig. 1; Fig.
4 shows a scintillation detector.
Fig. 5 is a view for explaining a conversion condition setting process in the neutron capture therapy apparatus of Fig. 1; Fig.
Fig. 6 is a view for explaining a conversion condition setting process in the neutron capture therapy apparatus of Fig. 1;

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of a neutron capture therapy apparatus and a neutron beam measurement method according to the present invention will be described in detail with reference to the drawings.

As shown in FIGS. 1 and 2, the neutron capture therapy apparatus 1 for performing cancer therapy using boron neutron capture therapy is a system in which boron (S) of patient (organism) (S) to which boron ( ^10B ) And irradiates neutron rays to the site where the cancer is treated. The neutron capture therapy apparatus 1 has an irradiation chamber 2 for irradiating a neutron beam N to a patient S constrained to the treatment zone 3 to perform cancer treatment of the patient S, A camera 4 for photographing the patient S is disposed. The camera 4 is, for example, a CCD camera.

The preparatory work such as restraining the patient S to the treatment table 3 is carried out in a preparation room (not shown) other than the examination room 2 and the treatment table 3, to which the patient S is bound, (2). The neutron capture therapy apparatus 1 further includes a neutron beam generating unit 10 for generating a neutron beam N for treatment and a neutron beam generating unit 10 for generating a neutron beam And a neutron beam irradiating unit 20 for irradiating the neutron beam N.

The neutron beam generating section 10 includes a cyclotron 11 for producing a charged particle beam L, a beam transport path 12 for transporting a charged particle beam L produced by the cyclotron 11, A charged particle ray scanning section 13 for scanning the line L to control irradiation of the charged particle beam L with respect to the target T and a target T. [ The cyclotron 11 and the beam transport path 12 are arranged in a chamber of a charged particle generating chamber 14 having a substantially rectangular shape and the charged particle generating chamber 14 is made of a concrete shielding wall W). The charged particle ray scanning section 13 controls the irradiation position of the charged particle beam L with respect to the target T.

The cyclotron 11 is an accelerator for accelerating charged particles such as protons to generate charged particle lines L such as quantum lines. This cyclotron 11 has the ability to generate a charged particle beam L of 60 kW (= 30 MeV x 2 mA) with a beam radius of 40 mm, for example. However, instead of the cyclotron 11, other accelerators such as synchrotron, synchrocyclotron, or lyaka can be used.

One end of the beam transport path (12) is connected to the cyclotron (11). The beam transport path 12 is provided with a beam adjusting section 15 for adjusting the charged particle beam L. [ The beam adjusting unit 15 includes horizontal steering and horizontal vertical steering for adjusting the axis of the charged particle beam L, quadruple electromagnet for suppressing divergence of the charged particle beam L, And a four-way slit that is shaped. However, the beam transport path 12 may have a function of transporting the charged particle beam L, and the beam adjusting unit 15 may be omitted.

The charged particle beam L transported by the beam transport path 12 is irradiated to the target T by controlling the irradiation position by the charged particle ray scanning section 13. [ However, the charged particle ray scanning section 13 may be omitted so that the charged particle beam L is irradiated to the same position of the target T at all times. The target T generates the neutron beam N by being irradiated with the charged particle beam L. The target T is made of, for example, beryllium (Be), lithium (Li), tantalum (Ta) or tungsten (W) and has a disk shape of 160 mm in diameter. The neutron beam N generated by the target T is irradiated toward the patient S in the irradiation chamber 2 by the neutron beam irradiation unit 20. [

The neutron irradiation unit 20 includes a moderator 21 for decelerating the neutron beam N emitted from the target T and a shield 22 for shielding the radiation such as the neutron beam N and gamma rays from being emitted to the outside The moderator 21 is constituted by the moderator 21 and the shielding body 22 constitutes a moderator.

The material of the moderator 21 is appropriately selected in accordance with various conditions such as the energy of the charged particle beam L. The material of the moderator 21 is appropriately selected depending on various conditions such as the energy of the charged particle beam L. [ Specifically, for example, when a beryllium target is used as the target T and a quantum wire having an output of 30 MeV from the cyclotron 11, the material of the moderator 21 may be lead, iron, aluminum or calcium fluoride have. When the output from the cyclotron 11 is 11 MeV and the beryllium target is used as the target T, the material of the moderator 21 may be a heavy water (D2O) or fluoride lead.

The shield 22 surrounds the moderator 21 and shields the radiation such as the gamma rays generated by the generation of the neutron beam N and the neutron beam N from the shield 22 Function. At least a part of the shielding body 22 is embedded in the wall W1 blocking the charged particle generation chamber 14 and the irradiation chamber 2. Between the irradiation chamber 2 and the shielding body 22, a wall body 23 constituting a part of the side wall surface of the irradiation chamber 2 is provided. The wall body 23 is provided with a collimator mounting portion 23a serving as an output port of the neutron beam N. A collimator 31 for fixing the irradiation range of the neutron beam N is fixed to the collimator mounting portion 23a.

The charged particle beam L is irradiated to the target T so that the target T generates the neutron beam N. In this case, The neutron beam N generated by the target T decelerates while passing through the moderator 21 and the neutron beam N emitted from the moderator 21 passes through the collimator 31 to be treated To the patient (S) on the stern (3). Here, as the neutron beam N, a thermo-gravitar or non-neutron beam having a relatively low energy can be used.

The treatment table 3 functions as a placement table used in the neutron capture therapy and restrains the patient S in a predetermined posture and holds the posture from the preparation chamber (not shown) to the examination chamber 2 And is movable. The treatment unit 3 includes a toe base 32 constituting the base of the treatment base 3, a caster 33 for allowing the toe base 32 to move on the floor surface, And a robot arm 35 for relatively moving the top plate 34 with respect to the toe portion 32. As shown in Fig.

The toe portion 32 has a rectangular parallelepiped base portion 32a and a rectangular parallelepiped support portion 32b which is positioned above the base portion 32a and supports the robot arm 35. [ The support portion 32b enters the base portion 32a and the robot arm 35 is fixed to the upper surface of the support portion 32b. Four casters 33 are mounted on the lower portion of the base portion 32a. Here, the driving force of a motor or the like may be given to the caster 33. In this case, since the caster 33 can be easily moved on the floor surface, the movement of the treatment table 3 in the horizontal direction is facilitated .

The robot arm 35 is for relatively moving the top plate 34 relative to the toe portion 32 and is capable of moving the patient S constrained on the top plate 34 relative to the collimator 31 . The top plate 34 has a substantially rectangular shape in plan view and the length of the top plate 34 in the longitudinal direction is set to a length (for example, 2 m) in which the patient S can lie on the top plate 34 have. The top plate 34 is capable of three-dimensionally adjusting the position with respect to the toe portion 32 as the robot arm 35 moves and rotates. The top plate 34 is provided with a restraining member (not shown) for restraining the patient S on the top plate 34.

The neutron beam N passing through the opening 31a of the collimator 31 is irradiated to the patient S restrained on the top plate 34. [ The collimator 31 has, for example, a substantially rectangular parallelepiped shape, and has an opening 31a for defining the irradiation range of the neutron beam N at the center thereof. The outer shape of the collimator 31 corresponds to the inner shape of the collimator mounting portion 23a of the wall body 23 and the collimator 31 is fixed in a state of being fitted to the collimator mounting portion 23a of the wall body 23 .

3, in the neutron capture therapy apparatus 1, the neutron beam N is irradiated to the patient S, and at the same time, the neutron beam N in the monitoring room 5 The neutron dose of the neutron beam N is output to the display 51 of the computer 50 in real time. Here, a part of the neutron beams irradiated from the neutron beam irradiating section 20 is irradiated to the scintillation detector (neutron beam detecting section) 41, and another part of the neutron beam is irradiated to the patient S. The scintillator 41a of the scintillation detector 41 shown in Fig. 4 is attached to the head of the patient S, for example. The scintillator 41a is a phosphor that converts the neutron beam incident on the scintillator 41a into light, and the internal crystal is excited according to the dose of the incident neutron beam to generate scintillation light.

The scintillation detector 41 includes a scintillator 41a, a light guide 41b for transmitting light from the scintillator 41a, and a light guide 41b for photoelectrically converting light transmitted by the light guide 41b, And a photodetector 41c for outputting an output signal E. The light guide 41b is composed of, for example, a bundle of flexible optical fibers, and transmits the light generated from the scintillator 41a to the photodetector 41c. The light guide 41b extends from the irradiation room 2 to the monitoring room 5 and is connected to the photodetector 41c in the monitoring room 5, for example. The photodetector 41c detects light from the light guide 41b and outputs an electric signal as a pulse signal to the signal processing circuit 42. [ As the photodetector 41c, for example, a phototube or a photomultiplier tube can be used.

The signal processing circuit 42 has a function of shaping a pulse signal from the scintillation detector 41 and outputting it to the neutron beam measuring section 43 and a noise removing function. 50 at the same time. The neutron beam measuring unit 43 is software in the computer 50 and counts the pulse of the pulse signal received from the signal processing circuit 42 to calculate the amount of the neutron beam N irradiated on the scintillator 41a as real Time is measured.

Here, the neutron beam measuring unit 43 measures the amount of the neutron beam N as the number of signals output by the scintillation detector 41 per unit time (counting rate). That is, the neutron beam measuring unit 43 measures data (hereinafter referred to as signal data) concerning the signal of the scintillation detector 41 and outputs the measured signal data of the scintillation detector 41 to the neutron dose output unit 44 . The real time dose output section 40 is constituted by the scintillation detector 41, the signal processing circuit 42, the neutron beam measuring section 43 and the neutron dose output section 44. [

Further, in the scintillation detector 41, the optical fiber of the light guide 41b is deteriorated as the number of irradiation of the neutron beam N increases, and the detection efficiency of the neutron beam N is lowered. Since the signal data from the scintillation detector 41 is gradually changed with respect to the amount of the neutron beam N irradiated to the scintillation detector 41 when the detection efficiency of the neutron beam N is lowered in this manner, (N) is lowered.

As a method of measuring the neutron beam N, there is a method of measuring the amount of irradiated neutron beam N by mounting a gold wire on the head of the patient S and measuring the amount of radiation of the gold wire have. As described above, the method of measuring the amount of neutrons (N) by measuring the amount of radiation of the gold wire is a method which is difficult to disturb the neutron field, and the amount of the neutron beam can be reliably detected by measuring the amount of the gamma ray emitted from the gold wire have. However, this method requires time for activation of the gold wire, and the amount of the neutron beam N can not be measured during the irradiation of the neutron beam N, which makes it impossible to perform real-time measurement. Further, since the total amount of the dose of the neutron beam N is calculated from the radiation amount of the gold wire, the average value of the dose per unit time can be calculated by dividing the total amount of the dose by the irradiation time, There is also the problem that change can not be calculated.

Therefore, in order to solve each of the above-mentioned problems, in the neutron capture therapy apparatus 1, the real time dose output unit 40 is capable of outputting the neutron dose in real time. The method of measuring the neutron beam N using the neutron capture therapy apparatus 1 has a real-time dose output step of outputting the neutron dose in real time. The neutron beam dose output section 44 of the real time dose output section 40 receives the signal data of the scintillation detector 41 from the neutron beam measuring section 43 and outputs the signal data to a preset correction coefficient 45, To the neutron dose of the neutron beam N, and outputs the dose of the neutron beam N in real time.

The correction coefficient 45 functions as a conversion condition for converting the signal of the scintillation detector 41 into the dose of the neutron beam N irradiated to the patient S and is a signal obtained by converting the signal data of the scintillation detector 41, And the dose of the neutron beam (N) irradiated to the sample (S). The correction coefficient 45 is set in advance in the calibration operation (conversion condition setting step) before the treatment. Here, "before treatment" indicates that each treatment is before treatment. However, the calibration may be performed for each predetermined number of times of treatment rather than before each treatment, or calibration may be performed after a predetermined time has elapsed. Hereinafter, this calibration operation and a method of measuring the neutron beam N at the time of treating the patient S using the neutron beam N will be described.

The calibration operation is performed, for example, when the patient S is not present in the examination room 2. [ As shown in Fig. 5 and Fig. 6, in the calibration operation, the correction coefficient setting unit (conversion condition setting unit) 60 sets the correction coefficient 45 before the treatment. The correction coefficient setting unit 60 includes a gold wire (metal member) 61 that is a thin line of gold (Au), a gamma ray detector (gamma ray detecting unit) 62 that detects gamma rays and a signal from the gamma ray detector 62 A neutron beam dose measuring section 64 for measuring the dose of the neutron beam N and a correction coefficient calculating section 65 for calculating the correction coefficient 45, .

5, the scintillation detector 41 is disposed, for example, at a position where the head portion of the patient S is positioned, and the gold wire 61 is disposed close to the scintillation detector 41. [ Here, the scintillation detector 41 and the gold wire 61 are arranged so that their position and direction with respect to the opening 31a of the collimator 31 become the same. Under this condition, the scintillation detector 41 and the gold wire 61 are irradiated with a neutron beam N for a predetermined time (for example, 10 minutes) (second neutron beam irradiation step). When the scintillation detector 41 is irradiated with the neutron beam N for a predetermined time, the neutron beam measuring unit 43 measures the signal data of the scintillation detector 41 in real time.

6, irradiation of the neutron beam N to the scintillation detector 41 and the gold wire 61 is stopped after the neutron beam N is irradiated for a predetermined time. The gold wire 61 emitted by the irradiation of the neutron beam N is carried out from the irradiation chamber 2 and placed in the holder in the monitoring room 5, for example. After the gold wire 61 is placed in the holder, the correction coefficient 45 is calculated by the gamma ray detector 62, the signal processing circuit 63, the neutron dose measuring section 64 and the correction coefficient calculating section 65 . The calculation process of the correction coefficient 45 is automatically performed by operating the computer 50 after the gold wire 61 is disposed.

The gamma ray detector 62 detects gamma rays generated from the radioactive gold wire 61 (gamma ray detection step). As the gamma ray detector 62, a semiconductor detector such as a germanium detector can be used. For example, when a gamma ray enters the semiconductor crystal of the gamma ray detector 62, an electric signal is generated. The gamma ray detector 62 outputs this electric signal to the signal processing circuit 63. [ The gamma ray detector 62 and the signal processing circuit 63 are disposed at a position adjacent to the computer 50 in the monitoring room 5, for example.

The signal processing circuit 63 has a function of shaping an electric signal from the gamma ray detector 62 and outputting it to the neutron dose measuring section 64 and a noise removing function. The neutron dose measuring unit 64 receives the electric signal shaped by the signal processing circuit 63 and measures the dose of the neutron beam N irradiated to the gold wire 61. [ Here, the neutron dose measuring unit 64 measures the amount of the neutron beam N as the amount of the neutron beam N per unit area, that is, the neutron flux (neutron beam bundle). The unit of the neutron dose measured by the neutron dose measuring unit 64 is, for example, N / cm ² . The dose of the neutron beam N measured by the neutron dose measuring section 64 is output to the correction coefficient calculating section 65. [

The dose of the neutron beam N measured by the neutron dose measuring unit 64 and the signal data of the scintillation detector 41 measured by the neutron beam measuring unit 43 are input to the correction coefficient calculating unit 65. [ The correction coefficient calculating section 65 calculates a correction coefficient 45 for associating the signal of the scintillation detector 41 with the neutron dose from the signal data of the scintillation detector 41 and the dose of the neutron beam N (Conversion condition calculating step). In this manner, after the correction coefficient 45 is calculated by the correction coefficient calculating section 65, a series of calibration operations are completed. Note that the correction coefficient 45 calculated here is the neutron dose measured by the neutron dose measuring unit 64 with respect to the unit data (the number of lights in the unit time) measured by the neutron beam measuring unit 43 .

After the calibration work is completed as described above, preparations such as restraining the patient S to the treatment table 3 are performed. The head of the patient S is moved to the opening 31a of the collimator 31 by driving the robot arm 35 after the treatment table 3 restrained by the patient S is moved into the examination room 2, The position of the patient S with respect to the collimator 31 is adjusted so that the irradiation position of the neutron beam N is positioned at the affected part of the patient S. [ Thereafter, the neutron beam N is irradiated to the patient S to start the treatment.

More specifically, as shown in FIG. 1, the cyclotron 11 generates a charged particle beam L, and the charged particle beam L passes through the beam transport path 12 and the charged particle beam scanning section 13 The target T is irradiated. Then, as shown in Fig. 2, the target T generates a neutron beam N (neutron beam generating step). The neutron beam N generated in the target T is irradiated to the patient S after the irradiation range is defined in the opening 31a of the collimator 31 after the neutron beam N is decelerated by the moderator 21 Research step).

Here, as shown in Fig. 3, the neutron beam N irradiated from the collimator 31 is incident on the scintillation detector 41. Fig. When the neutron beam N is incident on the scintillation detector 41, the signal data of the scintillation detector 41 is transmitted to the neutron beam measuring unit 43 through the signal processing circuit 42 in real time. The signal data of the scintillation detector 41 is converted into the dose of the neutron beam N by using the correction coefficient 45 by the neutron dose output unit 44 and is supplied to the display 51 of the computer 50 (Real time dose output step). Thus, since the dose of the neutron beam N is output to the display 51 in real time, the doctor or the like can see the dose of the neutron beam N at all times during treatment.

As described above, according to the method for measuring neutron beams using the neutron capture apparatus 1 and the neutron capture therapy apparatus 1, the neutron beam N irradiated by the neutron beam irradiating unit 20 is detected and the scintillation detector 41 detects the neutron beam N in real time And the signal data is converted into a neutron dose by a preset correction coefficient 45 by the neutron dose output section 44 and the neutron dose is output to the display 51 of the computer 50 in real time. By providing the real-time dose output section 40 having the scintillation detector 41 and the neutron dose output section 44 as described above, when the neutron beam N is irradiated and treated, The dose can be output in real time.

The correction coefficient setting unit 60 includes a gamma ray detector 62 that detects a gamma ray generated from the radioactive gold wire 61 irradiated with the neutron beam N and detects the neutron beam N (Updates) the correction coefficient 45 based on the signal data output from the scintillation detector 41 and the neutron dose acquired based on the gamma ray detected by the gamma ray detector 62. [ A scintillation detector 41 for outputting a signal by modifying the correction coefficient 45 by using the signal data output from the scintillation detector 41 and the neutron dose obtained from the gold wire 61 by detecting the neutron line N , The signal data of the scintillation detector 41 is corrected to the neutron dose by the corrected correction coefficient 45. [ That is, even if the detection efficiency of the scintillation detector 41 is lowered, the correction coefficient 45 is set again, so that the accurate neutron dose can be calculated. Therefore, the deviation of the measured neutron dose with respect to the actually irradiated neutron dose can be solved. In this manner, the signal data of the scintillation detector 41 is converted into the neutron dose by the corrected correction coefficient 45 and output, thereby avoiding the problem that the measurement accuracy of the neutron beam is lowered.

The neutron capture therapy apparatus 1 uses a scintillator 41a which generates an optical signal by being irradiated with a neutron beam as a neutron beam detection unit. Since the scintillator 41a is easy to be miniaturized and easily processed into various shapes, the scintillator 41a can be used to miniaturize the device.

The neutron beam measuring unit 43, the neutron dose output unit 44, the neutron dose measuring unit 64 and the correction coefficient calculating unit 65 are software in the computer 50 and include a signal processing circuit 42, The detector 62 and the signal processing circuit 63 are disposed at a position adjacent to the computer 50. In this manner, each device for performing the measurement operation and the calibration operation of the neutron beam N is concentrated in the monitoring room 5. [ The measuring operation and the calibration operation of the neutron beam N are automatically performed by the respective devices in the monitoring room 5 when the scintillation detector 41 and the gold wire 61 are set. Thus, the neutron capture therapy apparatus 1 has a configuration capable of easily performing the measurement work and the calibration work of the neutron beam N.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, but may be modified within the scope of the present invention.

In the above embodiment, the calibration operation is performed when the patient S is not present in the examination room 2, but the timing of performing the calibration operation can be appropriately changed. For example, the patient S may perform a calibration operation during the treatment that is present in the examination room 2. That is, when the entire irradiation time is set to 30 minutes, it is also possible to carry out the calibration work using the gold wire 61 for the first 10 minutes and to perform the real time measurement of the neutron dose for the following 20 minutes.

Although the gold wire 61 is used as the metal member of the correction coefficient setting unit 60, a metal member having a shape different from that of the gold wire 61, such as gold leaf, may be used. The material of the metal member is not limited to gold but can be used, for example, a material such as manganese which is activated when the neutron beam is irradiated.

In the above embodiment, the correction coefficient calculator 65 calculates the correction coefficient 45 from the signal data of the scintillation detector 41 and the dose of the neutron beam N. [ However, it is also possible to calculate the correction coefficient 45 from a signal other than the signal from the scintillation detector 41. For example, in calculation of the second and subsequent correction coefficients 45, the previous neutron dose output section 44 It is also possible to calculate the correction coefficient 45 from the output neutron dose and the neutron dose obtained by the present neutron dose measuring unit 64. [ The conversion condition for converting the signal data into the neutron dose is not limited to the correction coefficient 45, and for example, an equation or the like can be used.

In addition, although the scintillation detector 41 is used as a neutron beam detection unit that receives a neutron beam and generates a signal in real time, an ionization box may be used instead of the scintillation detector 41.

In the monitoring room 5, the computer 50, the gamma ray detector 62, and the signal processing circuits 42 and 63 are disposed at positions adjacent to each other. However, these arrangement positions may be changed as appropriate. It is also possible to appropriately change the configurations of the neutron beam generating unit 10 and the neutron beam irradiating unit 20 and the arrangements of the respective apparatuses in the neutron capture therapy apparatus 1. [

1: Neutron capture therapy device
10: Neutron beam generator
20: Neutron beam probe
40: Real time dose output unit
41: Scintillation detector (neutron beam detector)
41a: scintillator
44: Neutron dose output section
45: Correction factor (conversion condition)
60: correction coefficient setting section (conversion condition setting section)
61: Gold wire (metal member)
62: gamma ray detector (gamma ray detector)
N: Neutron line
S: Patient (subject)

Claims (3)

1. A neutron capture therapy apparatus for irradiating a neutron beam to a patient to be irradiated to perform cancer treatment,
A neutron beam generating unit for generating the neutron beam;
A neutron beam irradiator for irradiating the neutron beam generated by the neutron beam generator toward the irradiated object;
A neutron beam detector for detecting a neutron beam irradiated from the neutron beam irradiator and outputting a signal in real time; and a neutron beam detector for converting the signal output from the neutron beam detector into a neutron beam dose using a preset conversion condition, A real time dose output unit having a neutron dose output unit for outputting a neutron dose,
And a conversion condition setting unit for setting the conversion condition,
Wherein the conversion condition setting unit,
And a gamma ray detecting unit for detecting a gamma ray generated from the radioactive metal member upon irradiation with the neutron beam,
And corrects the conversion condition set in advance based on a signal output from the neutron beam detection unit upon irradiation with the neutron beam and a neutron beam dose of the neutron beam acquired based on the gamma ray detected by the gamma ray detection unit. Capture therapy devices. The method according to claim 1,
Wherein the neutron beam detection unit comprises:
A scintillator for converting an incident neutron beam into light,
A light guide for transmitting the light from the scintillator,
And a photodetector for photoelectrically converting the light transmitted by the light guide to output an electric signal,
Wherein the conversion condition setting unit modifies the conversion condition in accordance with deterioration of the light guide. The method according to claim 1,
Wherein the conversion condition setting unit modifies the conversion condition before each treatment.

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